Optimized projection computation

2024-10-06 14:53:21 +02:00 · 2017-04-02 22:18:03 +02:00 · 2017-04-02 22:18:03 +02:00 · e46bba18f2
commit e46bba18f2
parent a56aa4e706
3 changed files with 51 additions and 61 deletions
--- a/src/transversemercator.cpp
+++ b/src/transversemercator.cpp
@ -4,14 +4,6 @@
 #include "transversemercator.h"
 TransverseMercator::TransverseMercator()
 {
 	_centralMeridian = 0;
 	_scale = 1.0;
 	_falseEasting = 0;
 	_falseNorthing = 0;
 }
 TransverseMercator::TransverseMercator(double centralMeridian, double scale,
  double falseEasting, double falseNorthing)
 {
@ -19,48 +11,58 @@ TransverseMercator::TransverseMercator(double centralMeridian, double scale,
 	_scale = scale;
 	_falseEasting = falseEasting;
 	_falseNorthing = falseNorthing;
 	const double e2 = WGS84_FLATTENING * (2 - WGS84_FLATTENING);
 	const double n = WGS84_FLATTENING / (2 - WGS84_FLATTENING);
 	_rectifyingRadius = WGS84_RADIUS / (1 + n)
 	  * (1 + 0.25*pow(n, 2) + 0.015625*pow(n, 4));
 	_A = e2;
 	_B = (5 * pow(e2, 2) - pow(e2, 3)) / 6.0;
 	_C = (104 * pow(e2, 3) - 45 * pow(e2, 4)) / 120.0;
 	_D = (1237 * pow(e2, 4)) / 1260.0;
 	_beta1 = 1/2.0 * n - 2/3.0 * pow(n, 2) + 5/16.0 * pow(n, 3) + 41/180.0
 	  * pow(n, 4);
 	_beta2 = 13/48.0 * pow(n, 2) - 3/5.0 * pow(n, 3) + 557/1440.0 * pow(n, 4);
 	_beta3 = 61/240.0 * pow(n, 3) - 103/140.0 * pow(n, 4);
 	_beta4 = 49561/161280.0 * pow(n, 4);
 	_delta1 = 1/2.0 * n - 2/3.0 * pow(n, 2) + 37/96.0 * pow(n, 3) - 1/360.0
 	  * pow(n, 4);
 	_delta2 = 1/48.0 * pow(n, 2) + 1/15.0 * pow(n, 3) - 437/1440.0 * pow(n, 4);
 	_delta3 = 17/480.0 * pow(n, 3) - 37/840.0 * pow(n, 4);
 	_delta4 = 4397/161280.0 * pow(n, 4);
 	_AStar = e2 + pow(e2, 2) + pow(e2, 3) + pow(e2, 4);
 	_BStar = (7 * pow(e2, 2) + 17 * pow(e2, 3) + 30 * pow(e2, 4)) / -6;
 	_CStar = (224 * pow(e2, 3) + 889 * pow(e2, 4)) / 120;
 	_DStar = (4279 * pow(e2, 4)) / -1260;
 }
 QPointF TransverseMercator::ll2xy(const Coordinates &c) const
 {
 	QPointF p;
 	const double e2 = WGS84_FLATTENING * (2 - WGS84_FLATTENING);
 	const double n = WGS84_FLATTENING / (2 - WGS84_FLATTENING);
 	const double rectifyingRadius = WGS84_RADIUS / (1 + n)
 	  * (1 + 0.25*pow(n, 2) + 0.015625*pow(n, 4));
 	double A = e2;
 	double B = (5 * pow(e2, 2) - pow(e2, 3)) / 6.0;
 	double C = (104 * pow(e2, 3) - 45 * pow(e2, 4)) / 120.0;
 	double D = (1237 * pow(e2, 4)) / 1260.0;
 	double phi = deg2rad(c.lat());
 	double lambda = deg2rad(c.lon());
 	double lambda0 = deg2rad(_centralMeridian);
 	double deltaLambda = lambda - lambda0;
-	double phiStar = phi - sin(phi) * cos(phi) * (A + B*pow(sin(phi), 2)
+	double phiStar = phi - sin(phi) * cos(phi) * (_A + _B*pow(sin(phi), 2)
-	  + C*pow(sin(phi), 4) + D*pow(sin(phi), 6));
+	  + _C*pow(sin(phi), 4) + _D*pow(sin(phi), 6));
 	double xiPrim = atan(tan(phiStar) / cos(deltaLambda));
 	double etaPrim = atanh(cos(phiStar) * sin(deltaLambda));
-	double beta1 = 1/2.0 * n - 2/3.0 * pow(n, 2) + 5/16.0 * pow(n, 3)
+	p.ry() = _falseNorthing + _scale * _rectifyingRadius * (xiPrim + _beta1
-	  + 41/180.0 * pow(n, 4);
+	  * sin(2*xiPrim) * cosh(2*etaPrim) + _beta2 * sin(4*xiPrim)
-	double beta2 = 13/48.0 * pow(n, 2) - 3/5.0 * pow(n, 3) + 557/1440.0
+	  * cosh(4*etaPrim) + _beta3 * sin(6*xiPrim) * cosh(6*etaPrim) + _beta4
 	  * pow(n, 4);
 	double beta3 = 61/240.0 * pow(n, 3) - 103/140.0 * pow(n, 4);
 	double beta4 = 49561/161280.0 * pow(n, 4);
 	p.ry() = _falseNorthing + _scale * rectifyingRadius * (xiPrim + beta1
 	  * sin(2*xiPrim) * cosh(2*etaPrim) + beta2 * sin(4*xiPrim)
 	  * cosh(4*etaPrim) + beta3 * sin(6*xiPrim) * cosh(6*etaPrim) + beta4
 	  * sin(8*xiPrim) * cosh(8*etaPrim));
-	p.rx() = _falseEasting + _scale * rectifyingRadius * (etaPrim + beta1
+	p.rx() = _falseEasting + _scale * _rectifyingRadius * (etaPrim + _beta1
-	  * cos(2*xiPrim) * sinh(2*etaPrim) + beta2 * cos(4*xiPrim)
+	  * cos(2*xiPrim) * sinh(2*etaPrim) + _beta2 * cos(4*xiPrim)
-	  * sinh(4*etaPrim) + beta3 * cos(6*xiPrim) * sinh(6*etaPrim) + beta4
+	  * sinh(4*etaPrim) + _beta3 * cos(6*xiPrim) * sinh(6*etaPrim) + _beta4
 	  * cos(8*xiPrim) * sinh(8*etaPrim));
 	return p;
@ -68,38 +70,21 @@ QPointF TransverseMercator::ll2xy(const Coordinates &c) const
 Coordinates TransverseMercator::xy2ll(const QPointF &p) const
 {
-	const double e2 = WGS84_FLATTENING * (2 - WGS84_FLATTENING);
+	double xi = (p.y() - _falseNorthing) / (_scale * _rectifyingRadius);
-	const double n = WGS84_FLATTENING / (2 - WGS84_FLATTENING);
+	double eta = (p.x() - _falseEasting) / (_scale * _rectifyingRadius);
 	const double rectifyingRadius = WGS84_RADIUS / (1 + n)
 	  * (1 + 0.25*pow(n, 2) + 0.015625*pow(n, 4));
-	double xi = (p.y() - _falseNorthing) / (_scale * rectifyingRadius);
+	double xiPrim = xi - _delta1 * sin(2*xi) * cosh(2*eta) - _delta2 * sin(4*xi)
-	double eta = (p.x() - _falseEasting) / (_scale * rectifyingRadius);
+	  * cosh(4*eta) - _delta3 * sin(6*xi) * cosh(6*eta) - _delta4 * sin(8*xi)
 	double delta1 = 1/2.0 * n - 2/3.0 * pow(n, 2) + 37/96.0 * pow(n, 3)
 	  - 1/360.0 * pow(n, 4);
 	double delta2 = 1/48.0 * pow(n, 2) + 1/15.0 * pow(n, 3) - 437/1440.0
 	  * pow(n, 4);
 	double delta3 = 17/480.0 * pow(n, 3) - 37/840.0 * pow(n, 4);
 	double delta4 = 4397/161280.0 * pow(n, 4);
 	double xiPrim = xi - delta1 * sin(2*xi) * cosh(2*eta) - delta2 * sin(4*xi)
 	  * cosh(4*eta) - delta3 * sin(6*xi) * cosh(6*eta) - delta4 * sin(8*xi)
 	  * cosh(8*eta);
-	double etaPrim = eta - delta1 * cos(2*xi) * sinh(2*eta) - delta2 * cos(4*xi)
+	double etaPrim = eta - _delta1 * cos(2*xi) * sinh(2*eta) - _delta2
-	  * sinh(4*eta) - delta3 * cos(6*xi) * sinh(6*eta) - delta4 * cos(8*xi)
+	  * cos(4*xi) * sinh(4*eta) - _delta3 * cos(6*xi) * sinh(6*eta) - _delta4
-	  * sinh(8*eta);
+	  * cos(8*xi) * sinh(8*eta);
 	double phiStar = asin(sin(xiPrim) / cosh(etaPrim));
 	double deltaLambda = atan(sinh(etaPrim) / cos(xiPrim));
-	double AStar = e2 + pow(e2, 2) + pow(e2, 3) + pow(e2, 4);
+	double phi = phiStar + sin(phiStar) * cos(phiStar) * (_AStar + _BStar
-	double BStar = (7 * pow(e2, 2) + 17 * pow(e2, 3) + 30 * pow(e2, 4)) / -6;
+	  * pow(sin(phiStar), 2) + _CStar * pow(sin(phiStar), 4) + _DStar
 	double CStar = (224 * pow(e2, 3) + 889 * pow(e2, 4)) / 120;
 	double DStar = (4279 * pow(e2, 4)) / -1260;
 	double phi = phiStar + sin(phiStar) * cos(phiStar) * (AStar + BStar
 	  * pow(sin(phiStar), 2) + CStar * pow(sin(phiStar), 4) + DStar
 	  * pow(sin(phiStar), 6));
 	return Coordinates(_centralMeridian + rad2deg(deltaLambda), rad2deg(phi));
--- a/src/transversemercator.h
+++ b/src/transversemercator.h
@ -6,7 +6,6 @@
 class TransverseMercator : public Projection
 {
 public:
 	TransverseMercator();
 	TransverseMercator(double centralMeridian, double scale,
 	  double falseEasting, double falseNorthing);
@ -18,6 +17,12 @@ private:
 	double _scale;
 	double _falseEasting;
 	double _falseNorthing;
 	double _rectifyingRadius;
 	double _A, _B, _C, _D;
 	double _beta1, _beta2, _beta3, _beta4;
 	double _delta1, _delta2, _delta3, _delta4;
 	double _AStar, _BStar, _CStar, _DStar;
 };
 #endif // TRANSVERSEMERCATOR_H
--- a/src/utm.cpp
+++ b/src/utm.cpp
@ -1,6 +1,6 @@
 #include "utm.h"
-UTM::UTM(const Coordinates &c)
+UTM::UTM(const Coordinates &c) : _tm(0, 1.0, 0, 0)
 {
 	int zone = int((c.lon() + 180)/6) + 1;